Body-insertable apparatus, in-vivo information acquiring system, and body-insertable apparatus manufacturing method

ABSTRACT

An object of the present invention is to make it possible to closely examine a specific region by making most use of an advantage of a compound-eye capsule endoscope that picks up images of an interior of a body cavity forward and backward in a movement direction of a capsule casing. By disposing imaging devices of respective imaging blocks in a capsule casing while having a relationship between arrangement directions of the imaging devices, e.g., making upward and downward directions U and D coincident with each other, a correspondence/positional relationship between the images picked up by the imaging devices is clear when the specific region such as an affected part in the body cavity is to be observed using the respective images forward and backward in the movement direction, thereby facilitating close examination on the specific region using the both images.

CROSS-REFERNCE TO RELATED APPLICATIONS

This application is a continuation application of U.S. application Ser.No. 11/572,784 filed on Jan. 26, 2007, the content of which isincorporated herein by reference.

TECHNICAL FIELD

The present invention relates to a body-insertable apparatus such as acompound-eye capsule endoscope, an in-vivo information acquiring system,and a method of manufacturing a body-insertable apparatus.

BACKGROUND ART

In recent years, development of a swallowable capsule endoscope isunderway in the field of endoscopes. This capsule endoscope includes animaging function and a radio function. The capsule endoscope functionsto move in patient's organs, e.g., the esophagus, the stomach and thesmall intestine according to peristaltic movements of the organs and tosequentially pick up in-vivo images after it is swallowed from apatient's mouth for observation of the interior of a body cavity untilbeing naturally discharged (see, for example, Patent Document 1).

During the movement of the capsule endoscope in the body cavities, imagedata picked up in the body cavities by the capsule endoscope issequentially transmitted to the outside of the patient's body by radiocommunication and accumulated in a memory provided in a receiver outsideof the patient's body. A doctor or a nurse can diagnose the patientbased on images displayed on a display based on the image dataaccumulated in the memory.

Patent Document 1: Japanese Patent Application Laid-Open No. 2003-19111

Patent Document 2: Specification of U.S. Patent Application PublicationNo. 2002/109774

DISCLOSURE OF INVENTION Problem to be Solved by the Invention

Meanwhile, as the capsule endoscope of this type, a single-eyedendoscope that picks up only images of the body cavities (hereinafter,“body cavity images”) forward in the direction of the movement of theendoscope has been generally used. Recently, however, a compound-eyecapsule endoscope that picks up images forward and backward in thedirection of the movement of the endoscope has been proposed with a viewof enlarging the field of view during the observation of, for example,the esophagus (see, for example, Patent Document 2). This compound-eyecapsule endoscope is configured as follows. A plurality of imagingblocks each including an illuminating unit such as an LED forilluminating the interior of each body cavity and an imaging device suchas a CCD for picking up body cavity images is provided back and forth ina capsule casing. The imaging blocks pick up images forward and backwardin the direction of the movement of the capsule endoscope in the bodycavity.

Generally, the capsule endoscope passes through the esophagus at highspeed. Due to this, the single-eyed capsule endoscope often overlooks anabnormal site in the esophagus. If the compound-eye capsule endoscope isemployed, it can picks up more images even within short time because ofcapability of picking up images forward and backward in the direction ofthe movement of the capsule endoscope. It is, therefore, possible toreduce the frequency of overlooking abnormal sites. The small intestineis constituted by a relatively straight lumen, so that it generallysuffices to observe the small intestine from one side using thesingle-eyed capsule endoscope. The esophagus is largely constituted by astraight lumen. However, it has an asymmetric shape forward and backwardin the direction of the movement such as the esophageal orifice of thestomach. Due to this, if the compound-eye capsule endoscope that canobserve a region from both forward and backward in the direction of themovement of the endoscope is employed, the field of view can be secured.

The compound-eye capsule endoscope disclosed in the Patent Document 2 orthe like was proposed in such background. However, it is only describedtherein that the imaging devices pick up the images both forward andbackward in the direction of the movement. Specific configurations andthe like such as how to make effective use of advantages of thecompound-eye capsule endoscope are not at all mentioned.

The present invention has been achieved in view of the above-statedrespects. It is an object of the present invention to provide abody-insertable apparatus, an in-vivo information acquiring system, anda method of manufacturing a body-insertable apparatus capable of closelyinvestigating a specific region while making most use of the advantagesof a compound-eye capsule endoscope in that the field of view can beenlarged by picking up images forward and backward in the direction ofthe movement of a capsule casing in the body cavity.

Means for Solving Problem

A body-insertable apparatus includes a capsule casing; a plurality ofilluminating units, provided in the capsule casing, that illuminates aninterior of a body cavity; and a plurality of imaging devices, providedin the capsule casing while arrangement directions of the plurality ofimaging devices are associated with one another, that constitute imagingblocks, respectively together with the paired illuminating units, andthat pick up images of the interior of the body cavity at backward andforward in a movement direction of the capsule casing.

In the body-insertable apparatus according to the invention, each of theimaging devices of the respective imaging blocks may be disposed in thecapsule casing while making upward and downward directions of theimaging devices coincide with one another.

In the body-insertable apparatus according to the invention, each of theimaging devices of the respective imaging blocks may be disposed in thecapsule casing while making upward and downward directions of theimaging devices relatively deviated from one another by a predeterminedangle.

In the body-insertable apparatus according to the invention, each of theimaging devices of the respective imaging blocks may be disposed in thecapsule casing while making the upward and downward directions of theimaging devices differ by 180 degrees.

In the body-insertable apparatus according to the invention, each of theimaging devices of the respective imaging blocks may be arranged whilemaking upward and downward directions of the imaging devices to beeccentric to the center of an axis of the body-insertable apparatus.

In the body-insertable apparatus according to the invention, each of theimaging devices of the respective imaging blocks may behorizontally-long devices each having a predetermined aspect ratio.

In the body-insertable apparatus according to the invention, imagingdirections of each of the imaging devices of the respective imagingblocks may be set oblique direction to the center of an axis of thebody-insertable apparatus.

In the body-insertable apparatus according to the invention, each of theimaging devices of the respective imaging blocks may behorizontally-long devices each having a predetermined aspect ratio, anddisposed in the capsule casing while making upward and downwarddirections of the imaging devices differ by 90 degrees.

In the body-insertable apparatus according to the invention, each of theimaging devices of the respective imaging blocks may be generally squaredevices, and disposed in the capsule casing while making upward anddownward directions of the imaging devices may differ by 45 degrees.

In the body-insertable apparatus according to the invention, the capsulecasing may include a cylindrical body casing in which the respectiveimaging blocks may be disposed; and transparent end cover casings,provided watertight with the body casing, that may cover up therespective imaging blocks, and may derive illumination lights from theilluminating units, and wherein the body-insertable apparatus mayfurther comprise an elastic member that urges each of the imaging blocksagainst each of the end cover casings opposed to the respective imagingdevices.

In the body-insertable apparatus according to the invention, the elasticmember may be a spring member.

The body-insertable apparatus according to the invention may furtherinclude a light-shielding member held among the imaging blocks.

In the body-insertable apparatus according to the invention, thelight-shielding member may be a battery that supplies a power to theimaging devices and the illuminating units.

In the body-insertable apparatus according to the invention, thelight-shielding member may be a substrate on which the imaging devicesand the illuminating units are mounted.

In the body-insertable apparatus according to the invention, the capsulecasing may include a cylindrical body casing in which the respectiveimaging blocks are disposed; and transparent end cover casings, providedwatertight with the body casing, that covers up the respective imagingblocks, and derives illumination lights from the illuminating units, andwherein the body casing and one of the end cover casings may be formedintegrally into a bottomed casing.

In the body-insertable apparatus according to the invention, the bodycasing of the bottomed casing may be made of a colored materialimpermeable to a visible light.

An in-vivo information acquiring system may include the body-insertableapparatus; an acquiring unit that acquires the images of the interior ofthe body cavity, the images being picked up at time series by respectiveimaging devices of the body-insertable apparatus; and a displaycontroller that controls a display unit to display the images picked upand acquired by the respective imaging devices so as to correspond to arelationship among arrangement directions of the imaging devices.

In the in-vivo information acquiring system according to the invention,the display controller may control the images, picked up by therespective imaging devices made to coincide in upward and downwarddirections, to be displayed as they are.

In the in-vivo information acquiring system according to the invention,the display controller may control one of the images, picked up by therespective imaging devices made to coincide in upward and downwarddirections, to be displayed while being mirror-reversed.

In the in-vivo information acquiring system according to the invention,the display controller may control one of the images, picked up by therespective imaging devices made to relatively differ in upward anddownward directions by 180 degrees, to be displayed while being reversedin upward and downward directions.

In the in-vivo information acquiring system according to the invention,the display controller may control one of the images, picked up by therespective imaging devices made to relatively differ in upward anddownward directions by 90 degrees, to be displayed while being rotatedby 90 degrees.

In the in-vivo information acquiring system according to the invention,the display controller may control one of the images, picked up by therespective imaging devices made to relatively differ in upward anddownward directions by 45 degrees, to be displayed while being rotatedby 45 degrees.

A method of manufacturing a compound-eye body-insertable apparatus forpicking up the images of the interior of the body cavity at forward andbackward in a movement direction of the capsule casing, the methodincludes disposing in a capsule casing a plurality of imaging blockseach including an illuminating unit that illuminates an interior of abody cavity and an imaging device that picks up images of the interiorof the body cavity, the capsule casing including a cylindrical bodycasing, and transparent end cover casings, provided watertight with thebody casing, that covers up the respective imaging blocks, and derivesillumination lights from the illuminating units; forming a bottomedcasing by bonding one of the end cover casings to the body casing; andloading one of the imaging blocks into the formed bottomed casing whilepositioning one of the imaging blocks to an axial direction and acircumferential direction to the center of an axis of thebody-insertable apparatus, by dropping one of the imaging blocks intothe bottomed casing from an opening of the body casing.

Effect of the Invention

According to the body-insertable apparatus, the in-vivo informationacquiring system, and the method of manufacturing a body-insertableapparatus according to the present invention, the imaging devices ofrespective imaging blocks are disposed in the capsule casing whilehaving a relationship between arrangement directions of the imagingdevices. Therefore, a correspondence/positional relationship between theimages picked up by the imaging devices is clear when a specific regionsuch as an affected part in the body cavity is to be observed using therespective images forward and backward in the movement direction. It is,therefore, advantageously possible to facilitate close examination onthe specific region using the both images, and easily make most use ofthe advantage of the compound-eye capsule endoscope capable of enlargingthe field of view.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a pattern diagram showing an overall configuration of a radioin-vivo information acquiring system according to an embodiment of thepresent invention.

FIG. 2 is a cross-sectional view showing an internal configuration of acapsule endoscope.

FIG. 3 is a schematic perspective view typically showing a first exampleof the arrangement relationship between imaging devices.

FIG. 4 is a schematic perspective view typically showing a secondexample of the arrangement relationship between imaging devices.

FIG. 5 is an explanatory view showing the positional relationshipbetween imaging regions of the respective imaging devices in the secondexample.

FIG. 6 is a schematic perspective view typically showing a third exampleof the arrangement relationship between imaging devices.

FIG. 7 is an explanatory view showing the positional relationshipbetween imaging regions of the respective imaging devices in the thirdexample.

FIG. 8 is a schematic perspective view typically showing a fourthexample of the arrangement relationship between imaging devices.

FIG. 9 is an explanatory view showing the positional relationshipbetween imaging regions of the respective imaging devices in the fourthexample.

FIG. 10 is a block diagram showing a schematic configuration of adisplay device.

FIG. 11 is a schematic flowchart showing procedures of an image displayprocessing performed by a display controller.

FIG. 12 is schematic view showing an example of a display screen of adisplay unit in case of the first arrangement example.

FIG. 13 is schematic view showing another example of the display screenof the display unit in case of the first arrangement example.

FIG. 14 is schematic view showing an example of the display screen ofthe display unit in case of the second arrangement example.

FIG. 15 is schematic view showing an example of the display screen ofthe display unit in case of the third arrangement example.

FIG. 16 is an exploded cross-sectional view showing a method ofmanufacturing a capsule endoscope.

FIG. 17 is a cross-sectional view showing an example of a configurationof a capsule endoscope according to a first modification.

FIG. 18 is a cross-sectional view showing an example of a configurationof a capsule endoscope according to a second modification.

EXPLANATIONS OF LETTERS OR NUMERALS

3 Capsule endoscope

11 a, 11 b Illuminating unit

12 a, 12 b Imaging device

14 a, 14 b Imaging block

16 Capsule casing

16 a, 16 b End cover casing

16 c Body casing

16′ Bottomed casing

29 Battery

30 Spring member

41 Input unit

42 Display unit

46 Display controller

BEST MODE(S) FOR CARRYING OUT THE INVENTION

A radio in-vivo information acquiring system as an exemplary embodimentof a body-insertable apparatus according to the present invention willbe described hereinafter with reference to the accompanying drawings. Itis to be noted that the present invention is not limited by theembodiment. In the drawings, same or corresponding constituent elementsare denoted by the same reference symbols, respectively.

The embodiment of the present invention will be described. FIG. 1 is apattern diagram showing an overall configuration of the radio in-vivoinformation acquiring system. The in-vivo information acquiring systemuses a compound-eye capsule endoscope as an example of thebody-insertable apparatus. As shown in FIG. 1, the radio in-vivoinformation acquiring system includes a capsule endoscope 3, which isinserted into the body of a subject 1, which picks up a body cavityimage and radio-transmits data such as an image signal to the receivingapparatus 2, a receiving apparatus 2, which receives the data on the abody cavity image radio-transmitted from the capsule endoscope 3, adisplay device 4, which displays the body cavity image based on theimage signal received by the receiving apparatus 2, and a portablerecording medium 5, which mediates between the receiving apparatus 2 andthe display device 4 for transmitting and receiving data between thereceiving apparatus 2 and the display device 4. The receiving apparatus2 includes a radio unit 2 a including a plurality of receiving antennasA1 to An attached to the body surface of the subject 1, and a mainreceiving unit 2 b that performs a processing and the like on a radiosignal received through the receiving antennas A1 to An. These units aredetachably connected to each other through a connector or the like.Alternatively, each of the receiving antennas A1 to An can be providedon, for example, a jacket which the subject can wear, and can beattached to the subject 1 by causing the subject 1 to wear the jacket.Moreover, in this alternative, the receiving antennas A1 to An can bedetachably provided on the jacket.

The display device 4, which displays the body-cavity image picked up bythe capsule endoscope 3, is configured, like a workstation or the like,to display images based on the data obtained by the portable recordingmedium 5. Specifically, the display device 4 can be configured todirectly display images by a CRT display, a liquid crystal display orthe like or to output images to the other medium.

A compact flash (registered trademark) memory or the like is used as theportable recording medium 5. The portable recording medium 5 isdetachable from the main receiving unit 2 b and the display device 4,and functions to be able to output or record information when beingattached to the main receiving unit 2 b or the display device 4.Specifically, the portable recording medium 5 is attached to the mainreceiving unit 2 b while the capsule endoscope 3 is moving in bodycavities of the subject 1, and the data transmitted from the capsuleendoscope 3 is recorded in the portable recording medium 5. After thecapsule endoscope 3 is discharged from the subject 1, that is, after theinterior of the subject 1 is imaged, the portable recording medium 5 isdetached from the main receiving unit 2 b and attached to the displaydevice 4. The display device 4 reads the recorded data. By allowing theportable recording medium 5 to mediate between the main receiving unit 2b and the display device 4 for transmitting and receiving datatherebetween, the subject 1 can move freely while the body cavities arebeing imaged. The portable recording medium 5 also contributes toreduction in time for transmitting and receiving the data between themain receiving unit 2 b and the display device 4. Alternatively, theother recording device included in the main receiving unit 2 b can usedto mediate between the main receiving unit 2 b and the display device 4for transmitting and receiving data therebetween, and the otherrecording medium can be connected to the display device 4 by wired orradio connection.

Referring now to FIG. 2, the capsule endoscope 3 will be described. FIG.2 is a cross-sectional view showing an internal configuration of thecapsule endoscope 3. The capsule endoscope 3 is configured to includetwo imaging blocks 14 a and 14 b, which include illuminating units 11 aand 11 b, serving as illuminators, for illuminating the interior of eachbody cavity of the subject 1, and imaging devices 12 a and 12 b, e.g.,CCDs or CMOSs, for picking up images of the body cavity, respectively,as well as a power supply unit 15 that supplies power to the imagingblocks 14 a and 14 b in a capsule casing 16.

The capsule casing 16 includes end cover casings 16 a and 16 b, whichcover up the imaging blocks 14 a and 14 b, respectively and which aretransparent and semicircular dome-shaped, and a cylindrical body casing16 c, which are provided to be watertight with the end cover casings 16a and 16 b through concavo-convex engagement members 17 a and 17 b andin which the imaging blocks 14 a and 14 b are provided with a powersupply unit 15 present therebetween, respectively. The capsule casing 16is formed to be large enough to be swallowable from the mouth of thesubject 1. The body casing 16 c is made of a colored material thatcannot transmit visible light.

The imaging units 13 a and 13 b include imaging devices 12 a and 12 bprovided on imaging substrates 18 a and 18 b and imaging rangesilluminated by illumination lights from the illuminating units 11 a and11 b, respectively, imaging lenses 21 a and 21 b forming subject imageson the imaging devices 12 a and 12 b and including moving lenses 19 aand 19 b and fixed lenses 20 a and 20 b, respectively. The moving lenses19 a and 19 b are fixed to moving frames 22 a and 22 b, the fixed lenses20 a and 20 b are fixed to fixed frames 23 a and 23 b, therebyconstituting focus adjusters 24 a and 24 b, respectively.

Furthermore, the illuminating units 11 a and 11 b are constituted by,for example, light-emitting diodes (LEDs), mounted on the illuminationsubstrates 25 a and 25 b, and provided at four locations, i.e., upward,downward, left, and right locations around a center of an optical axisof the imaging lenses 21 a and 21 b, respectively. Moreover, in theimaging blocks 14 a and 14 b, signal processor/controllers 26 a and 26 bfor processing or controlling the respective constituent elements of theblocks are provided on rear surfaces of the imaging substrates 18 a and18 b, respectively. Furthermore, a radio substrate 28 on which a radiounit 27 including an antenna and the like for holding a radiocommunication with the outside is mounted, is provided in the signalprocessor/controller 26 a of one imaging block 14 a. The imagingsubstrates 18 a and 18 b are appropriately, electrically connected tothe illumination substrates 25 a and 25 b by cables, respectively.

The power supply unit 15 located between the imaging blocks 14 a and 14b is constituted by, for example, a button battery having a diameteralmost identical to an inside diameter of the body casing 16 c. As thebattery 29, a silver oxide battery, a rechargeable battery, apower-generation battery or the like can be employed. In centralportions between the imaging blocks 14 a and 14 b and the battery 29,spring members 30 a and 30 b each in the form of a torsion coil springare provided to serve as elastic members that urge the respectiveimaging blocks 14 a and 14 b toward the end casings 16 a and 16 bopposed each other, that is, toward outside, respectively. The radiounit 27 on the radio substrate 28 is appropriately, electricallyconnected to the signal processor/controller 26 b by a cable or the likepassed through the outside of the battery 29. Likewise, the battery 29is appropriately, electrically connected to the signalprocessors/controllers 26 a and 26 b and the like by cables or the like.The radio unit 27 can be provided for each of the imaging blocks 14 aand 14 b without being shared between the imaging blocks 14 a and 14 b.

Positioning units 31 a and 31 b are formed integrally near outercircumferences of interiors of the end cover casings 16 a and 16 b,respectively. By striking and thereby abutting a part of outerperipheral sides of the illumination substrates 25 a and 25 b againstthe positioning units 31 a and 31 b, respectively, the imaging blocks 14a and 14 b are axially positioned in the capsule endoscope 3 based onthe positioning units 31 a and 31 b. Furthermore, anti-rotationpositioning units (not shown) are formed between the positioning units31 a and 31 b and the illumination substrates 25 a and 25 b,respectively. The anti-rotation positioning units, each of which isconstituted by a combination of convex and concave members engageablewith each other, function to axially position the imaging blocks 14 aand 14 b, respectively.

The arrangement relationship between the imaging devices 12 a and 12 bin the capsule endoscope 3 will next be described with reference toFIGS. 3 to 9. The imaging devices 12 a and 12 b are disposed in thecapsule casing 16 associated therewith according to devicecharacteristics such as imaging regions of the imaging devices 12 a and12 b. FIG. 3 is a schematic perspective view typically showing a firstexample of the arrangement relationship between the imaging devices 12 aand 12 b. In the first example, devices which are identical in structureand two-dimensional imaging surfaces 32 a and 32 b of which are formedto be generally square are used as the imaging devices 12 a and 12 b,respectively. The imaging devices 12 a and 12 b are disposed in thecapsule casing 16 to form the arrangement relationship therebetween soas to coincident in upward and downward directions with respect tocenter of axis direction. The imaging devices 12 a and 12 b are disposedin the capsule casing 16 while circumferential directions of the imagingdevices 12 a and 12 b with respect to the center of axis direction beingpositioned so that, if upward, downward, left, and right directions ofthe forward-looking imaging device 12 a are, for example, U, D, L, and Ras shown in FIG. 3, respectively, upward and downward directions U and Dof the backward-looking imaging device 12 b coincide with those of theimaging direction 12 a and so that only left and right directions L andR of the imaging device 12 b are opposite to those of the imaging device12 a. It is to be noted that the upward, downward, left, and rightdirections of the imaging devices 12 a and 12 b are defined by thedirection of a two-dimensional scan on the imaging surfaces 32 a and 32b (that is, the direction of repeating a left-to-right scan thereon fromupward to downward), and not by vertical direction.

FIG. 4 is a schematic perspective view typically showing a secondexample of the arrangement relationship between the imaging devices 12 aand 12 b. In the second example, devices which are identical instructure and two-dimensional imaging surfaces 32 a and 32 b of each ofwhich is formed horizontally long and has a predetermined aspect ratioare used as the imaging devices 12 a and 12 b, respectively. Examples ofthe predetermined aspect ratio include 4:3, 3:2, and 16:9. In the secondexample, the predetermined aspect ratio is, for example, 16:9.

In the second example, the imaging devices 12 a and 12 b are disposed inthe capsule casing 16 to have the arrangement relationship so that theupward and downward directions of the imaging devices 12 a and 12 b aredeviated by a predetermine dangle. Specifically, the imaging devices 12a and 12 b are provided to differ in upward and downward directions by90 degrees. The imaging devices 12 a and 12 b are disposed in thecapsule casing 16 while circumferential directions of the imagingdevices 12 a and 12 b with respect to the center of axis direction beingpositioned so that, if upward, downward, left, and right directions ofthe forward-looking imaging device 12 a are, for example, U, D, L, and Ras shown in FIG. 4, respectively, upward and downward directions U and Dof the backward-looking imaging device 12 b differ from those of theimaging device 12 a by 90 degrees. Similarly to FIG. 3, the upward,downward, left, and right directions of the imaging devices 12 a and 12b are defined by the direction of the two-dimensional scan on theimaging surfaces 32 a and 32 b (that is, the direction of repeating theleft-to-right scan thereon from upward to downward) and not by thevertical direction.

FIG. 6 is a schematic perspective view typically showing a third exampleof the arrangement relationship between the imaging devices 12 a and 12b. In the third example, similarly to the second example, devices whichare identical in structure and two-dimensional imaging surfaces 32 a and32 b of each of which is formed horizontally long and has apredetermined aspect ratio, e.g., 16:9 are used as the imaging devices12 a and 12 b, respectively.

In the third example, the imaging devices 12 a and 12 b are disposed inthe capsule casing 16 to have the arrangement relationship therebetweenso that the upward and downward directions of the imaging devices 12 aand 12 b are disposed eccentric to the center of an axis of the capsuleendoscope 3, and deviated from each other by a predetermined angle.Specifically, the imaging devices 12 a and 12 b are provided while theirupward and downward directions differ from each other by 180 degrees,i.e., while they are reversed with respect to each other. The imagingdevices 12 a and 12 b are disposed in the capsule casing 16 whilecircumferential directions of the imaging devices 12 a and 12 b withrespect to the center of an axis direction being positioned so that, ifupward, downward, left, and right directions of the forward-lookingimaging device 12 a are, for example, U, D, L, and R as shown in FIG. 6,upward and downward directions U and D of the backward-looking imagingdevice 12 b differ by 180 degrees from those of the imaging device 12 a.

FIG. 8 is a schematic perspective view typically showing a fourthexample of the arrangement relationship between the imaging devices 12 aand 12 b. In the fourth example, similarly to the first example, deviceswhich are identical in structure and two-dimensional imaging surfaces 32a and 32 b of which are formed to be generally square are used as theimaging devices 12 a and 12 b, respectively.

Such imaging devices 12 a and 12 b are disposed in the capsule casing 16to have the arrangement relationship therebetween so as to deviate fromeach other in upward and downward directions by a predetermined angle.Specifically, the imaging devices 12 a and 12 b are provided to differfrom each other in upward and downward directions by 45 degrees. Theimaging devices 12 a and 12 b are disposed in the capsule casing 16while circumferential directions of the imaging devices 12 a and 12 bwith respect to the center of an axis direction being positioned sothat, if upward, downward, left, and right directions of theforward-looking imaging device 12 a are, for example, U, D, L, and R asshown in FIG. 8, upward and downward directions U and D of thebackward-looking imaging device 12 b differ from those of the imagingdevice 12 a by 45 degrees.

The capsule endoscope 3 configured to be thus arranged sequentiallymoves in the body cavities after the subject 1 swallows the capsuleendoscope 3 from his/her mouth at the time of carrying out anexamination on the subject 1. During the movement of the capsuleendoscope 3 in the body cavity such as the esophagus, a front image ofthe interior of the body cavity is picked up, for example, by theimaging device 12 a while the illuminating units 11 a of the imagingblock 14 a located forward illuminate a forward part in the body cavity,subjected to necessary processings by the signal processor/controller 26a, radio-transmitted to the receiving apparatus 2 by the radio unit 27,classified in a folder F1 as one frame image of the front image, andrecorded in the portable recording medium 5 at certain timing. Atanother timing subsequent to the certain timing, a rear image of theinterior of the body cavity is picked up by, for example, the imagingdevice 12 b while the illuminating units 11 b of the imaging block 14 blocated backward illuminate a backward part in the body cavity,subjected to necessary processings by the signal processor/controller 26b, radio-transmitted to the receiving apparatus 2 by the radio unit 27,classified in a folder F2 paired with the folder F1 as one frame imageof the rear image, and recorded in the portable recording medium 5.

At this time, image-processing instruction information at the time ofimage display based on the arrangement relationship between the imagingdevice 12 b and the imaging device 12 a identified for every capsuleendoscope 3 is also recorded, as header information for the folder F2,in a recording region of the portable recording medium 5 in which regionthe frame image transmitted from the imaging device 12 b is recorded.For example, if the imaging devices 12 a and 12 b are arranged torelatively differ in upward and downward directions by 90 degrees asdescribed in the second example, information on an instruction toperform a 90-degree rotation processing is additionally recorded as theheader information. If the imaging devices 12 a and 12 b are arranged torelatively differ in upward and downward directions by 180 degrees asdescribed in the third example, information on an instruction to performa reversed processing between upward and downward directions isadditionally recorded as the header information. If the imaging devices12 a and 12 b are arranged to relatively differ in upward and downwarddirections by 45 degrees as described in the fourth example, informationon an instruction to perform a 45-degree rotation processing isadditionally recorded as the header information. If the imaging devices12 a and 12 b are arranged to coincide in upward and downward directionsas described in the first example, ‘no processing’ (‘no instruction’)can be set initially as information on an image processing instructionduring image display. Furthermore, information on an instruction toperform a mirror-reversal processing can be additionally recorded as theheader information according to a request from the user or the like.

In this manner, front images and rear images are alternately repeatedlypicked up by the imaging devices 12 a and 12 b in a time-divisionfashion. By doing so, more images of even a region, e.g., the esophagus,through which the capsule endoscope 3 quickly passes within short timecan be picked up by picking up images forward and backward in thedirection of the movement of the capsule endoscope 3. Moreover, even ifthe region is asymmetric longitudinally, the field of view can besecured since the asymmetric region is observed from both forward andbackward.

If the arrangement relationship between the two imaging devices 12 a and12 b is not held so that the two imaging devices 12 a and 12 b areassociated with each other, the following disadvantages occur. Even ifabnormal sites such as lesion sites or bleeding sites are present in theimages picked up by the respective imaging devices 12 a and 12 b, it isimpossible to determine whether the sites are identical. This reducesthe merit of the compound-eye capsule endoscope capable of imaging aregion of interest in both forward and backward directions by half. Ifthe imaging devices 12 a and 12 b picks up images of the bleeding siteor a depressed (depressed lesion) site, in particular, it is difficultto determine how the images picked up by the respective imaging devices12 a and 12 b are associated, as compared with a protruding portion suchas a polyp. According to the first example of the capsule endoscope 3 inthe embodiment, by contrast, the imaging devices 12 a and 12 b aredisposed in the capsule casing 16 while having the arrangementrelationship therebetween so as to coincide in upward and downwarddirections. Because of the clear correspondence and arrangementrelationship between the imaging devices 12 a and 12 b, if a specificregion such as an affected part in the body cavity is to be observedfrom the images forward and backward in the movement direction of thecapsule endoscope 3, it is possible to easily, accurately determinewhether the abnormal site present in the forward image is identical withthat present in the backward image and to easily carry out a closeexamination on the specific region using the both images. In the firstarrangement example, in particular, the imaging devices 12 a and 12 bare provided to be associated with each other so as to coincide inupward and downward directions. Therefore, the same region can be pickedup twice only by changing imaging directions, so that the same regioncan be closely observed.

In the second to fourth arrangement examples, the imaging ranges of theimaging devices 12 a and 12 b can be made associated with each other soas to mutually cover the field of view. It is, therefore, possible tosecure a wide field of view in each of the body cavities. FIG. 5 is anexplanatory view showing the positional relationship between imagingregions 71 and 72 of the imaging devices 12 a and 12 b in case of thesecond example. The horizontally long imaging regions 71 and 72corresponding to the imaging devices 12 a and 12 b form an orthogonalarrangement relationship therebetween to correspond to the orthogonalarrangement relationship between the imaging devices 12 a and 12 b withrespect to the axial direction of the capsule endoscope 3. The interiorof the body cavity is imaged in this orthogonal arrangementrelationship. An imaging region of the imaging lenses 21 a and 21 b isindicated by, for example, a broken-line circle in FIG. 5. In this case,each of the horizontally-long imaging devices 12 a and 12 b hasinsufficient coverage in upward and downward directions. However, byorthogonally arranging the imaging devices 12 a and 12 b and, therefore,making the imaging regions 71 and 72 orthogonal to each other, theimaging ranges (fields of view) of the imaging devices 12 a and 12 b canbe made associated with each other so as to be able to mutually coverthe regions which they cannot observe solely. It is, therefore, possibleto image each body cavity while reducing the frequency of overlookingabnormal sites.

Likewise, FIG. 7 is an explanatory view showing the positionalrelationship between imaging regions 71 and 72 of the imaging devices 12a and 12 b in case of the third example. The horizontally-long imagingregions 71 and 72 corresponding to the imaging devices 12 a and 12 bform a upward and downward reversed arrangement relationshiptherebetween to correspond to the upward and downward reversedarrangement relationship between the imaging devices 12 a and 12 b withrespect to the axial direction of the capsule endoscope 3. The interiorof the body cavity is imaged in this upward and downward reversedarrangement relationship. An imaging region of the imaging lenses 21 aand 21 b is indicated by, for example, a broken-line circle in FIG. 7.In this case, each of the horizontally-long imaging devices 12 a and 12b has insufficient coverage in upward and downward directions. However,by arranging the upward and downward directions of the imaging devices12 a and 12 b to be eccentric to the center of axis of the capsuleendoscope 3 and, therefore, setting the imaging regions 71 and 72reversed directions between the upward and downward directions withrespect to each other, the imaging device 12 a images an upper side inthe body cavity as the imaging region 71, and the imaging device 12 bimages a lower side as the imaging region 72. The imaging ranges (fieldsof view) of the imaging devices 12 a and 12 b can be made associatedwith each other so as to be able to mutually cover the regions whichthey cannot observe solely. It is, therefore, possible to image eachbody cavity while reducing the frequency of overlooking abnormal sites.

Moreover, FIG. 9 is an explanatory view showing the positionalrelationship between imaging regions 73 and 74 of the imaging devices 12a and 12 b. The imaging regions 73 and 74 corresponding to the imagingdevices 12 a and 12 b form an arrangement relationship therebetween tocorrespond to the 45-degree-rotation arrangement relationship betweenthe imaging devices 12 a and 12 b with respect to the center of axisdirection of the capsule endoscope 3. The interior of the body cavity isimaged in this arrangement relationship. An imaging region of theimaging lenses 21 a and 21 b is indicated by, for example, a broken-linecircle in FIG. 9. In this case, each of the imaging devices 12 a and 12b has insufficient coverage in upward, downward, left, and rightdirections. However, by arranging the imaging devices 12 a and 12 b tobe rotated by 45 degrees with respect to the imaging device 12 b andvice versa, therefore, arranging the imaging regions 73 and 74 to bedifferent by 45 degrees, the imaging regions of the imaging devices 12 aand 12 b are closer to the imaging region (circle) of the imaging lenses21 a and 21 b. The imaging ranges (fields of view) of the imagingdevices 12 a and 12 b can be made associated with each other so as to beable to mutually cover the regions which they cannot observe solely. Itis, therefore, possible to image each body cavity while reducing thefrequency of overlooking abnormal sites.

Furthermore, the body casing 16 c is made of the colored material whichis not transparent to the visible light. However, since the compound-eyecapsule endoscope 3 includes a plurality of imaging blocks 14 a and 14b, while one imaging device, e.g., the imaging device 12 a is picking upan image, the illumination light from the illuminating unit 11 b for theother imaging device 12 b possibly enters the imaging region of theimaging device 12 as a stray light through a route of an internalclearance or the like. As a result, the quality of the picked-up imagemay possibly be degraded. The same thing is true for the relationshipbetween the imaging device 12 b and the illuminating unit 11 a.According to the embodiment, by contrast, the battery 29 almost equal indiameter to the body casing 16 c and present between the imaging blocks14 a and 14 b functions as a light-shielding member. It is, therefore,possible to prevent degradation of the quality of the picked-up imagebecause of the influence on one imaging device, of the illuminatinglight from the other imaging device when the imaging device 12 a or 12 bpicks up an image. Alternatively, a substrate formed almost equal indiameter to the body casing 16 c can be used as the light-shieldingmember either in place of or together with the battery 29.

Referring to FIG. 10, the display device 4 will be described. FIG. 10 isa block diagram showing a schematic configuration of the display device4 shown in FIG. 1. As shown in FIG. 10, the display device 4 includes aninput unit 41, a display unit 42, a storage unit 43, and a control unit44.

The input unit 41, which is realized by a pointing device such as akeyboard or a mouse, receives instruction information on an operationinstruction to the display device 4 or on an instruction of processingsperformed by the display device 4, and transmits each instructioninformation to the control unit 44. The display unit 42, which isrealized by a CRT display, a liquid crystal display or the like,displays instruction information from the input unit 41, an instructionresult or the like. The display unit 42 includes predetermined imagedisplay regions in which image groups Pa and Pb stored in the pairedfolders Fl and F2 in the storage unit 43 are displayed in parallel, andthe like.

The storage unit 43, which is realized by, for example, a hard diskdevice, holds various images acquired from the portable recording device5. In the embodiment, for example, the image group Pa including aplurality of frame images picked up by the imaging device 12 a in thecapsule endoscope 3 is stored in the folder Fl. The image group Pbincluding a plurality of frame images picked up by the imaging device 12b in the capsule endoscope 3 is stored in the folder F2 paired with thefolder F1 for every capsule endoscope 3. Frame numbers are assigned tothe respective images in the image groups Pa and Pb stored in thefolders F1 and F2 in order of reception of image data by the receivingapparatus 2. Moreover, as already stated, the folder F2 includes aheader-information storage region in which the image processinginstruction information at the time of image display based on thearrangement relationship between the imaging devices 12 a and 12 bidentified for every capsule endoscope 3 is stored.

The control unit 44 controls processings or operations performed by theinput unit 41, the display unit 42, and the storage unit 43,respectively. The control unit 44 includes an image processor 45, adisplay processor 46, and an image selector 47. The image processor 45functions to perform image processings such as a mirror-reversalprocessing, a upward and downward reversal processing, a 90-degreerotation processing, and a 45-degree rotation processing on each image.The image processor 45 appropriately performs the image processing oneach frame image included in the image groups Pa and Pb. The displaycontroller 46 functions to control a display processing performed by thedisplay unit 42. In the embodiment, the display controller 46particularly controls the display unit 42 to display images in parallelin a predetermined image display region based on the image groups Pa andPb stored in the folders F1 and F2, respectively. The image selector 47extracts and outputs the images one by one from the image groups Pa andPb stored in the respective folders F1 and f2 according to frame rate inorder of frame numbers so as to perform the image processing on or todisplay the images.

Referring next to FIG. 11, procedures of the image display processingperformed by the display controller 46 will be described. Referring toFIG. 11, it is first determined whether instruction information on aninstruction to display both a front image and a rear image picked up bythe capsule endoscope in parallel is received from the input unit 41(step S1). If it is determined that the instruction information isreceived (step S1: Yes), the display controller 46 instructs the imageselector 47 to read header information from the header informationstorage region in the folder F2 (step S2), and to sequentially selectand read the images in the image groups Pa and Pb stored in therespective folders F1 and F2 in order of frame number (step S3). Thecontent of the header information in the header-information storageregion in the folder F2 is determined (steps S4 to S7).

First, if this header information is free from instruction (step S4:Yes), the display controller 46 controls the display unit 42 to displaythe frame images read from the folders F1 and F2 in the image displayregion in parallel one by one without processing them (step S12). If theheader information includes the mirror-reversal instruction (step S5:Yes), then the image processor 45 subjects the frame image read from thefolder F2 to the mirror-reversal processing (step S8), and the displaycontroller 46 controls the display unit 42 to display the frame imageread from the folder F1 and the frame image read from the folder F2 andsubjected to the mirror-reversal processing in the image display regionin parallel (step S12).

If a 90-degree rotation instruction is stored (step S6: Yes), then theimage processor 45 subjects the frame image read from the folder F2 tothe 90-degree rotation processing (step S9), and the display controller46 controls the display unit 42 to display the frame image read from thefolder F1 and the frame image read from the folder F2 and subjected tothe 90-degree rotation processing in the image display region inparallel (step S12).

If a upward and downward reversal instruction is stored (step S7: Yes),then the image processor 45 subjects the frame image read from thefolder F2 to the upward and downward reversal processing (step S10), andthe display controller 46 controls the display unit 42 to display theframe image read from the folder F1 and the frame image read from thefolder F2 and subjected to the upward and downward reversal processingin the image display region in parallel (step S12).

If a 45-degree rotation instruction is stored (step S7: No), the imageprocessor 45 subjects the frame image read from the folder F2 to the45-degree rotation processing (step S11), and the display controller 46controls the display unit 42 to display the frame image read from thefolder F1 and the frame image read from the folder F2 and subjected tothe 45-degree rotation processing in the image display region inparallel (step S12).

Thereafter, it is determined whether instruction information on aninstruction to finish image display is received (step S13). If it isdetermined that this instruction information is received (step S13:Yes), the display controller 46 controls the display unit 42 to finishimage display. If it is determined that the instruction information onthe instruction to finish image display is not received (step S13: No),it is determined whether the display unit 42 displays the frame imagesup to the final frame image (step S14). If it is determined that thedisplay unit 42 does not display the frame images up to the final frameimage (step S14: No), the processing at and after the step S3 isrepeatedly performed.

Referring next to FIGS. 12 to 15, examples of the images displayed inparallel on a display screen of the display unit 42 will be described.FIG. 12 is a schematic view showing an example of the display screen ofthe display unit 42 in case of the steps S4 and S12. The display screenof the display unit 42 includes a main observation monitor 51 fordisplaying examination images picked up by the imaging devices 12 a and12 b. In the embodiment, using this main observation monitor 51, theimages picked up by the imaging devices 12 a and 12 b are displayed inparallel.

In FIG. 12, reference symbol 52 denotes a filing list block fordisplaying a list of examination dates, and a list of patient names isdisplayed per examination date. If one patient name under oneexamination date is selected, a first image of the patient for anexamination is displayed on the main observation monitor 51. Referencesymbol 53 denotes a play controller for changing play methods on themain observation monitor 51, and the play controller 53 selectablyincludes PLAY, PAUSE, FRAME-BY-FRAME ADVANCE, PLAY TOP, PLAY END buttonsand the like. If one play button is selected in the play controller 53,still images are continuously displayed on the main observation monitor51, thereby pseudo-displaying a moving image. Reference symbol 54 denotea play-speed change button for changing over a play speed between twospeeds of low speed/high speed. Reference symbol 55 denotes anumber-of-displayed-images change button for changing the number ofimages to be displayed on the observation monitor 51 to one/two/four.For example, by selecting two as the number of displayed images andinstructing two images to be displayed by thisnumber-of-displayed-images change button 55, the examination imagespicked up by the imaging devices 121 a and 12 b are displayed left andright in parallel on the observation monitor 51. Reference symbol 56denotes an image-processing mark bar an entire length of which is setto, for example, ten hours, and the image-processing mark bar 56displays a temporal position of each image which is being played.

Reference symbol 57 denotes an image picked up by double-clicking on theimage that is being displayed on the observation monitor 51. The image57 is reduced-displayed in a selected image list block 58. At the sametime, positions of the image-processing mark bar 56 corresponding to theselected images are connected to upper portions of the respectiveselected images by lines, thus clearly expressing a temporallypositional relationship.

FIG. 12 shows an example in which a front image 61 and a rear image 62picked up by the imaging devices 12 a and 12 b almost at the same timingare displayed side by side in parallel on the main observation monitor51 according to the display control processing at the steps S4 and S12shown in FIG. 11. Namely, the front image 61 is an example of the imageobtained by causing the imaging device 12 a to image a part in a forwarddirection in the body cavity, and the rear image 61 is an example of theimage obtained by causing the imaging device 12 b to image a part in abackward direction in the body cavity. In case of the first arrangementexample, the images picked up by the imaging devices 12 a and 12 b aredisplayed without performing such a processing as rotation. Due to this,the forward image and the backward image are displayed in parallel asthey are. However, it is determined that the arrangement relationshipbetween the imaging devices 12 a and 12 b is such that they coincide inupward and downward directions and are opposite only in left and rightdirections. Therefore, the doctor or nurse who looks at the displayscreen shown in FIG. 12 can recognize that the correspondence/positionalrelationship between the two images 61 and 62 is bilateral symmetry. Forexample, the doctor or nurse can easily, accurately determine that anabnormal site appearing leftward in the front image 61 is identical withthat appearing rightward in the rear image 62.

FIG. 13 is a schematic view showing an example of the display screen ofthe display unit 42 if information indicating the mirror-reversalprocessing is added as header information in response to a request fromthe user or the like in the first arrangement example (at the steps S5and S12). In FIG. 13, images picked up by the imaging devices 12 a and12 b are displayed in parallel using the main observation monitor 51. Incomparison to FIG. 12, the rear image 62 obtained by causing the imagingdevice 12 b to pick up a part in the body cavity in the backwarddirection is displayed in a mirror-reversed manner in FIG. 13. Namely,in the example of FIG. 12, the arrangement relationship between theimaging devices 12 a and 12 b is such that the imaging devices 12 a and12 b coincide in upward and downward directions and are opposite only inleft and right directions. On the other hand, in the example of FIG. 13,the image picked up by one imaging device 12 b is mirror-reversed andthe mirror-reversed image is displayed. Therefore, both the images 61and 62 can be observed as if a car driver looks at rear side through aback mirror (looks at the rear image 62) while looking at front sidethrough a front glass (looking at the front image 61), and the displayedimages coincide in lateral direction. This can facilitate determiningthe correspondence/positional relationship between the images 61 and 62and accelerate diagnosis. For example, it is possible to easily,accurately determine that an abnormal site appearing leftward in thefront image 61 is identical with an abnormal site appearing leftward inthe rear image 62.

FIG. 14 is a schematic view showing an example of the display screen ofthe display unit 42 in case of the steps S6 and S12 accompanied by the90-degree rotation instruction in the second arrangement example. InFIG. 14, images 63 and 64 picked up by the imaging devices 12 a and 12 bare displayed in parallel using the main observation monitor 51. In FIG.14, the front image 63 picked up by one imaging device 12 a is displayedas it is whereas the rear image 64 picked up by the other imaging device12 b is displayed as a vertically-long image by being rotated by 90degrees. Namely, the imaging device 12 b is provided while its upwardand downward directions are rotated by 90 degrees. However, when theimage picked up by the imaging device 12 b is to be displayed, theupward and downward directions of the imaging device 12 b is notcorrected to coincide with display vertical direction but the imagepicked up by the imaging device 12 b is displayed while its upward anddownward directions are made to coincide with that in which the imagingdevice 12 a picks up the image. By doing so, the images 63 and 64 aredisplayed in parallel while making the imaging devices 12 a and 12 bcoincide in upward and downward directions in which the imaging devices12 a and 12 b pick up the images 63 and 64, respectively. Thecorrespondence/positional relationship between the images 63 and 64 is,therefore, easier to determine.

FIG. 15 is a schematic view showing an example of the display screen ofthe display unit 42 in case of steps S7 and S12 accompanied by theupward and downward reversal instruction in the third arrangementexample. In FIG. 15, images 63 and 64 picked up by the imaging devices12 a and 12 b are displayed above and below in parallel using the mainobservation monitor 51. In FIG. 15, the front image 63 picked up by theimaging device 12 a is displayed as it is whereas the rear image 64picked up by the other imaging device 12 b is displayed while upward anddownward directions being reversed to each other. Namely, the imagingdevice 12 b is provided while its upward and downward directions arerotated by 180 degrees. However, when the image picked up by the imagingdevice 12 b is to be displayed, the upward and downward directions ofthe imaging device 12 b is not corrected to coincide with the displayvertical direction but the image picked up by the imaging device 12 b isdisplayed while its upward and downward directions are made to coincidewith that in which the imaging device 12 a picks up the image by thereversal processing of upward and downward directions. By doing so, theimages 63 and 64 are displayed above and below in parallel while makingthe imaging devices 12 a and 12 b coincide in upward and downwarddirections in which the imaging devices 12 a and 12 b pick up the images63 and 64, respectively. The correspondence/positional relationshipbetween the images 63 and 64 is, therefore, easier to determine.

Referring to FIG. 16, a method of manufacturing the capsule endoscope 3according to the embodiment will be described. FIG. 16 is an explodedcross-sectional view showing the method of manufacturing the capsuleendoscope 3 according to the embodiment. First, a bottomed casing 16′ isformed by bonding one end cover casing 16 b to the body casing 16 c byadhesive (step [1]). The imaging block 14 b is attached into thebottomed casing 16′ by dropping the imaging block 14 b from an opening16 d of the body casing 16 c (step [2]). By abutting and contacting theillumination substrate 25 b of the imaging block 14 b against and withthe positioning unit 31 b by the dropping operation, the imaging block14 b is axially positioned. At the same time, the anti-rotationpositioning units are engaged with each other by slightly rotating theimaging block 14 b in the bottomed casing 16′, thereby positioning theimaging block 14 b around the axis of the bottomed casing 16′. It isthereby possible to attach the imaging block 14 b into the bottomedcasing 16′ with high assembly accuracy.

Subsequently to attachment of the imaging block 14 b, the battery 29 isattached into the bottomed casing 16′ by dropping the battery 29thereinto (step [3]), the other imaging block 14 a is attached into thebottomed casing 16's by dropping the imaging block 14 a thereinto (step[4]), and the end cover casing 16 a is bonded to the opening 16 d of thebody casing 16 c (step [5]). The capsule endoscope 3 is therebycompleted. Alternatively, the end cover casing 16 a can be bonded to theopening 16 d of the body casing 16 c while the imaging block 14 a isattached into the end cover casing 16 a.

By abutting and contacting the illumination substrate 25 a of theimaging block 14 a against and with the positioning unit 31 a by such anoperation, the imaging block 14 a is axially positioned. At the sametime, the anti-rotation positioning units are engaged with each other byappropriately rotating the imaging block 14 a in the bottomed casing16′, the imaging block 14 a is positioned around the axis of thebottomed casing 16′. The imaging block 14 a can be thereby attached intothe bottomed casing 16′ with high assembly accuracy.

If signs such as marks for positioning the anti-rotation positioningunits are put between the body casing 16 c and the respective end covercasings 16 a and 16 b, and positions of the anti-rotation positioningunits of the end cover casings 16 a and 16 b are made to conform to eachother in, for example, the first arrangement example, the imagingdevices 12 a and 12 b of the imaging blocks 14 a and 14 b attached intothe capsule casing 16 can be disposed to coincide in upward and downwarddirections with each other.

In case of the second arrangement example, the positions of theanti-rotation positioning units of the end cover casings 16 a and 16 bare made different from each other by 90 degrees, the imaging devices 12c and 12 d of the imaging blocks 14 a and 14 b attached into the capsulecasing 16 can be disposed to differ in upward and downward directions by90 degrees. In case of the third arrangement example, the positions ofthe anti-rotation positioning units of the end cover casings 16 a and 16b are made different from each other by 180 degrees, the imaging devices12 a and 12 b of the imaging blocks 14 a and 14 b attached into thecapsule casing 16 can be disposed to differ in upward and downwarddirections by 180 degrees. In case of the fourth arrangement example,the positions of the anti-rotation positioning units of the end covercasings 16 a and 16 b are made different from each other by 45 degrees,the imaging devices 12 a and 12 b of the imaging blocks 14 a and 14 battached into the capsule casing 16 can be disposed to differ in upwardand downward directions by 45 degrees.

In this manner, in the method of manufacturing the capsule endoscope 3according to the embodiment, even if the capsule endoscope 3 is acompound-eye capsule endoscope, the bottomed casing 16′ is formed inadvance by bonding one end cover casing 16 b to the body casing 16 c. Itis thereby possible to attach contents such as the imaging blocks 14 band 14 a into the capsule casing 16 by dropping them from one direction,and to improve assembly performance. Furthermore, the imaging blocks 14a and 14 b are positioned by the positioning unit 13 a axially andaround the axis of the capsule casing 16, and urged against the endcover casings 16 a and 16 b with the spring members 30 a and 30 b heldbetween the battery 29 and the imaging blocks 14 a and 14 b,respectively. It is, therefore, possible to improve the assemblyaccuracy and maintain the high assembly accuracy.

First Modification

Referring to FIG. 17, a first modification will be described. FIG. 17 isa cross-sectional view showing an example of a configuration of thecapsule endoscope 3 according to the first modification. In theembodiment, the bottomed casing 16′ is formed by bonding one end covercasing 16 b to the body casing 16 c by adhesive. In the firstmodification, an end cover casing 16 b′ and a body casing 16 c areintegrally formed as a bottomed casing 16″ in advance. By doing so, thecapsule endoscope 3 can be assembled by dropping the imaging blocks 14 aand 14 b from one direction as described above with reference to FIG.16.

In the bottomed casing 16″, the end cover casing 16′ is required to betransparent to the visible light, and the body casing 16 c′ is requirednot to be transparent to the visible light. Therefore, in the firstmodification, when the bottomed casing 16″ is formed by integrating theend cover casing 16 b′ with the body casing 16 c′, the body casing 16 c′is formed out of a colored material untransparent to the visible lightby coinjection molding. Alternatively, the entire bottomed casing 16″can be formed integrally by a transparent material while either aninterior or an exterior of the body casing 16 c′ is colored by applyingpaint thereto.

Second Modification

Referring to FIG. 18, a second modification will be described. FIG. 18is a cross-sectional view showing an example of an internalconfiguration of the capsule endoscope 3 according to the secondmodification. The capsule endoscope 3 in the second modification isconfigured so that the imaging blocks 14 a and 14 b are disposed in thecapsule casing 16 while optical axis directions (imaging directions) ofthe imaging blocks 14 a and 14 b are set not to parallel but oblique tothe axis of the capsule casing 3. By arranging the imaging blocks 14 aand 14 b obliquely, the positioning units 31 a and 31 b of the end covercasings 16 a and 16 b are formed not to be orthogonal but to be obliqueto the axis of the capsule endoscope 3. While the end cover casings 16 aand 16 b are bonded to the body casing 16 c, the positioning units 31 aand 31 b are set to be parallel to each other. Furthermore, as thespring members 30 a and 30 b, doglegged springs are employed to urge theimaging blocks 14 a and 14 b against the oblique positioning units 31 aand 31 b, respectively.

Moreover, the imaging devices 12 a and 12 b included in the respectiveimaging blocks 14 a and 14 b are disposed in the capsule casing 16 whilehaving the arrangement relationship therebetween so as to deviate inupward and downward directions by a predetermined angle. Specifically,the imaging devices 12 a and 12 b are provided to differ in upward anddownward directions by 180 degrees, that is, vertically reversed withrespect to each other. Similarly to the preceding embodiment, the imagespicked up by these imaging devices 12 a and 12 b can be displayed while,for example, the image picked up by the imaging device 12 b isvertically reversed.

According to the second modification, the imaging directions of therespective imaging devices 12 a and 12 b are set obliquely to the axisof the capsule endoscope 3. Due to this, when the interior of the bodycavity is to be imaged, an upper side in the body cavity can be imagedas a front image by the imaging device 12 a and a lower side thereof canbe imaged as a rear image by the imaging device 12 b. It is therebypossible to reduce the frequency of overlooking abnormal sites in thebody cavity.

The present invention is not limited to the above-stated embodiments andvarious modifications can be made of the present invention as long asthey do not depart from the scope of the present invention.

INDUSTRIAL APPLICABILITY

As stated so far, the body-insertable apparatus, the in-vivo informationacquiring system, and the method of manufacturing an in-vivo informationacquiring system according to the present invention are suited as acompound-eye capsule body-insertable apparatus, a compound-eye in-vivoinformation acquiring system, and a method of manufacturing acompound-eye in-vivo information acquiring system capable of imaging aregion of interest from both forward and backward and enlarging thefield of view.

1. A body-insertable apparatus comprising: a plurality of imagingblocks; a plurality of illuminating units; a cylindrical body casing inwhich the imaging blocks and the illuminating units are disposed; aplurality of transparent end cover casings, provided watertight with thebody casing, that cover up the respective imaging blocks and theilluminating units; and an elastic member that urges each of the imagingblocks against each of the end cover casings opposed to the respectiveimaging blocks.
 2. The body-insertable apparatus according to claim 1,wherein the elastic member is a spring member.
 3. The body-insertableapparatus according to claim 1, further comprising a light-shieldingmember held among the imaging blocks.
 4. The body-insertable apparatusaccording to claim 3, wherein the light-shielding member is a batterythat supplies a power to the imaging blocks and the illuminating units.5. The body-insertable apparatus according to claim 3, wherein thelight-shielding member is a substrate on which the imaging blocks andthe illuminating units are mounted.
 6. The body-insertable apparatusaccording to claim 1, wherein the body casing and one of the end covercasings are formed integrally into a bottomed casing.
 7. Thebody-insertable apparatus according to claim 6, wherein the body casingof the bottomed casing is made of a colored material impermeable to avisible light.
 8. The body-insertable apparatus according to claim 1,wherein the body casing provides a concave portion, the end covercasings provides a convex portion, and an elastic force of the elasticmember is supported by a fitting between the concave portion and theconvex portion.
 9. The body-insertable apparatus according to claim 8,wherein the concave portion is provided on a fitting portion of the bodycasing almost circumferentially.